KR101427055B1 - Intra-frame code diversity - Google Patents

Abstract

A method and apparatus are disclosed for encoding portions of user data with user data in a corresponding spreading sequence within a frame associated with a single user. Specifically, by associating a first portion of a frame with a first portion of user data and associating a second portion of a frame with a second portion of user data, Lt; RTI ID = 0.0 > link. ≪ / RTI > The first and second portions of the user data are then encoded with different spreading sequences. Transmits the user data from the first radio to the second radio by transmitting a first portion of the encoded user data in the first portion of the frame and a second portion of the encoded user data in the second portion of the frame.

Description

DATA TRANSMISSION METHOD, DATA TRANSMITTING APPARATUS, AND CODE DIVERSITY TRANSMITTER [0001]

The present invention relates to mobile wireless signal diversity, and more particularly to encoding downlink and uplink mobile wireless data transmitted from a single source to a plurality of timeslots within a frame, wherein portions of the data are different Encoded in a spreading sequence.

And transmits data in a CDMA wireless system by transmitting a code sequence for each bit or data symbol. Each user is assigned a different code. When a user transmits data on multiple channels, each user channel is assigned a different code. By using different codes, a plurality of users can transmit signals within the same frequency band within the same time slot. Generally, these codes are designed to have good cross-correlation properties. If the cross-correlation properties are good, then the receiver is able to correlate the received composite signal comprising a plurality of codes to separate one or more individually coded signals from the composite signal.

Good cross-correlation properties between groups of selected codes are not always obtainable. In addition, before the signal reaches the receiver, multipath in the wireless channel may change the cross-correlation property of the signal. Therefore, the cross-correlation between signals may be good and the cross-correlation may be deteriorated. Poor cross-correlation can result in inadequate radio link performance, increased burst of data errors, and loss of spectral efficiency of the system.

According to an aspect of the present invention, there is provided a method of transmitting data over a plurality of timeslots in a frame over a link from a first radio to a second radio, the method comprising receiving a first portion of user data and a first portion of a frame Associating the portion; Associating a second portion of the user data with a second portion of the frame; Encoding a first portion of user data into a first spreading sequence; Encoding a second portion of the user data with a second spreading sequence, wherein the first spreading sequence is different from the second spreading sequence; Transmitting a first portion of the encoded user data in a first portion of a frame from a first wireless to a second wireless; And transmitting a second portion of the encoded user data in a second portion of the frame from the first wireless to the second wireless.

Some embodiments of the invention provide a method wherein a timeslot includes a first portion of a frame and a second portion of a frame. Some embodiments of the present invention provide that a first portion of a frame includes a first timeslot of a frame and a second portion of the frame includes a second timeslot of a frame, . Some embodiments of the invention provide a method wherein the first timeslot and the second timeslot are adjacent timeslots. Some embodiments of the invention provide a method wherein the first timeslot and the second timeslot are time slots separated by one or more timeslot periods.

Some embodiments of the present invention comprise a method comprising: encoding a third portion of user data into a third spreading sequence; Encoding a fourth portion of the user data with a fourth spreading sequence, wherein the fourth spreading sequence is different from the third spreading sequence; Transmitting a third portion of the encoded user data in a first portion of a second frame from a first radio to a second radio, wherein a first portion of the second frame corresponds to a first portion of the first frame ; Transmitting a fourth portion of encoded user data in a second portion of a second frame from a first radio to a second radio, wherein a second portion of the second frame corresponds to a second portion of the first frame The method comprising the steps of: Some embodiments of the present invention provide a method further comprising performing forward error correction across a plurality of time slots in a frame.

Some embodiments of the present invention provide a method further comprising performing an interleave over a plurality of time slots. Some embodiments of the present invention provide a method wherein the first spreading sequence comprises a first scrambling code, the second spreading sequence comprises a second scrambling code and the first scrambling code is different from the second scrambling code. Some embodiments of the present invention include transmitting a first portion of encoded user data in a first portion of a frame from a first radio to a second radio comprises transmitting a first midamble sequence, Transmitting a second portion of the encoded user data in a second portion of the first midamble sequence from a first radio to a second radio comprises transmitting a second midamble sequence wherein the first midamble sequence comprises a second mid- It provides an alternative to the amble sequence.

Some embodiments of the present invention provide a method comprising: determining a first spreading sequence for a first portion of user data; And determining a second spreading sequence for a second portion of the user data. Some embodiments of the invention provide a method wherein the link includes an uplink, wherein the first radio includes a mobile radio and the second radio includes a base station. Some embodiments of the present invention provide a method wherein the link includes a downlink, wherein the first radio includes a base station and the second radio includes a mobile radio.

According to another aspect of the present invention, there is provided an apparatus comprising: logic for accepting user data; Code mapping and distribution logic, the code mapping and distribution logic being operative to parse the user data into a first portion of user data and a second portion of user data; Encoding logic operative to encode a first portion of user data into a first spreading sequence and to encode a second portion of user data into a second spreading sequence different from the first spreading sequence; A code diversity transmitter is provided that includes a transmitter coupled to the encoding logic and operative to transmit encoded user data.

Some embodiments of the present invention are forward error correction (FEC) logic that operates to perform forward error correction on user data, the FEC logic including forward error correction (FEC) logic coupled between logic accepting user data and code mapping and distribution logic A code diversity transmitter further comprising correction logic. Some embodiments of the present invention provide interleaved logic, the interleaving logic further comprising interleaving logic coupled between the logic accepting user data and code mapping and distribution logic. Some embodiments of the present invention provide a code diversity transmitter in which a first portion of user data comprises time slot blocks of data. Some embodiments of the present invention provide a code diversity transmitter in which the first spreading sequence comprises a first scrambling code, the second spreading sequence comprises a second scrambling code and the first scrambling code is different from the second scrambling code.

According to yet another aspect of the present invention there is provided an apparatus for transmitting data over a plurality of timeslots in a frame over a link from a first radio to a second radio, Means for associating a first portion of the first portion of the image; Means for associating a second portion of the frame with a second portion of user data; Means for encoding a first portion of user data into a first spreading sequence; Means for encoding a second portion of user data with a second spreading sequence, wherein the first spreading sequence is different from the second spreading sequence; Means for transmitting a first portion of encoded user data in a first portion of a frame from a first wireless to a second wireless; And means for transmitting a second portion of the encoded user data in a second portion of the frame from the first wireless to the second wireless.

Other features and aspects of the present invention will now be described, by way of example, with reference to the accompanying drawings, which illustrate, by way of example, the features of the embodiments of the present invention. The above summary of the present invention is not intended to limit the scope of the present invention, and the scope of the present invention is defined only in the appended claims.

In some embodiments of the invention, the method changes the scrambling code assigned to the cell on a timeslot basis. To enable accurate decoding, the variation pattern may be known to both the user and the base station, and may be synchronized between the transmitter and the receiver. In some embodiments of the invention, the code variation pattern is predetermined and known a priori by the transmitter and the receiver. In some embodiments of the invention, the code variation pattern is signaled to the user terminal by the network at the beginning of the connection or during the connection. In some embodiments of the invention, the code variation pattern is derived by an algorithm known to both the transmitter and the receiver, and the seed-value or other parameter is signaled at the beginning or during the connection. In some embodiments of the invention, the code variation pattern is a function of system parameters known to both the transmitter and the receiver. For example, the system parameter may be a system frame number. Further, in some embodiments of the present invention, the code variation pattern itself may be changed at a predetermined time when it is determined or signaled by the network or a priori known to both the receiver and the transmitter.

In some embodiments of the invention, the spreading codes used may be generated from a conventional set of predetermined scrambling and channelization sequences, or may be generated from entirely new sequences. In another approach, a new set of sequences may be derived using computing means or algorithm means that utilize an existing sequence as function inputs.

In some embodiments of the present invention, the midamble sequence used for transmission may also be changed in the same manner as for the code applied to the payload section of the burst (s).

Some embodiments of the present invention provide a TDD CDMA system comprising a transmitter capable of altering a code sequence used for transmission more than once during transmission of one or more interleaved forward error correction data units, wherein the code diversity advantage And a transmission method in a TDD CDMA system. The code sequence may be changed multiple times within the radio frame. Some embodiments of the present invention provide a receiver that is synchronized with a variation code pattern provided in a transmitter to perform deinterleaving and error correction decoding of the received data unit (s).

An embodiment of the present invention provides a method for changing transmission code at least once upon transmission of a forward error correction data unit by means of modifying a scrambling code, wherein the scrambling code used is (1) for 3GPP TDD CDMA Originating from an existing set of scrambling codes; (2) derived by computing means or algorithm means from an existing set of scrambling codes determined for 3GPP TDD CDMA; And / or (3) any new set of scrambling codes. Some embodiments of the present invention provide a method for changing a transmission code more than once during transmission of a forward error correction data unit by means of modifying the channelization code, wherein the channelization code comprises: (1) Are members of a set of channelization codes determined for the channelization code; And / or (2) any new set of channelization codes. Some embodiments of the present invention provide a method for changing a transmission code more than once during transmission of a forward error correction data unit by means of modifying both the scrambling code and the channelization code. Some embodiments of the present invention provide a method for altering a transmission code upon transmission of a forward error correction data unit by means of applying an additional code to an existing channelization code and a scrambling code.

Some embodiments of the present invention provide a method in which the code variation pattern is known a priori and implicitly to both the transmitter and the receiver. Some embodiments of the present invention provide a way in which a code variation pattern is explicitly signaled to a transmitter by a network or a base station. Some embodiments of the present invention provide that code variation patterns are derived through algorithm means or computation means based on parameters; Signaled to the transmitter by the network or base station; And / or other system parameters known to both the transmitter and the receiver, or signaled to the transmitter by the network. Some embodiments of the invention provide a way in which the transmitted code is changed in time slot units. Some embodiments of the invention provide a way in which the transmitted code is changed on a sub-timeslot basis (e.g., per data payload, per payload, or per symbol). Some embodiments of the present invention provide a method by which the transmitted code is changed per time slot or sub time slot by means of changing scrambling code and / or channelization code and / or additional provided code.

Some embodiments of the present invention provide a method as described for any of the above-described features provided in 3GPP TDD CDMA uplink systems, including legacy uplink channels and / or enhanced uplink channels. Some embodiments of the present invention provide a method as described for any of the above-described features provided in a 3GPP TDD CDMA downlink system, including legacy downlink channels, HSDPA and future downlink channels. Some embodiments of the present invention provide any of the methods described above in which the midamble sequence used for burst transmission is also changed as a variation function applied to the scrambling / channelization / additional code.

BRIEF DESCRIPTION OF THE DRAWINGS Embodiments of the invention will now be described by way of example with reference to the accompanying drawings, in which: Fig.
1 shows a model of an uplink TDD CDMA encoding, transmission and reception system according to some embodiments of the present invention.
2 shows a TDD CDMA timeslot burst according to some embodiments of the present invention.
Figure 3 illustrates a form of code diversity using frame-based cell ID cycling in accordance with some embodiments of the present invention.
4 illustrates a code diversity transmission scheme for low latency transmission in accordance with some embodiments of the present invention.
5 illustrates a form of code diversity using time slot based ID cycling in accordance with some embodiments of the present invention.

In the following description, reference is made to the accompanying drawings which illustrate several embodiments of the present invention. It is to be understood that other embodiments may be utilized and that variations in mechanical, combined, structural, electrical, and operational aspects may be made without departing from the spirit and scope of the present invention. The following description is not intended to be construed in a limiting sense, but the scope of embodiments of the present invention is defined only by the claims.

Some portions of the detailed description that follow are described by symbolic representations of procedures, steps, logic blocks, processing, and other operations on data bits that may be performed on a computer memory. Here, procedures, computer execution steps, logic blocks, processing, etc., are considered to be consistent sequences or instructions of the steps that produce the desired results. These steps are physical manipulations of physical quantities. These physical quantities can take the form of electrical, magnetic, or radio signals that can be stored, transmitted, combined, compared, and otherwise manipulated in a computer system. These signals may sometimes be referred to as bits, values, elements, symbols, characters, terms, numbers, and the like. Each step may be performed in hardware, software, firmware, and combinations thereof.

Some CDMA systems select a spreading code from a set of defined values. In some CDMA systems, such as the 3GPP UTRA TDD / FDD system, a spreading code may be composed of two components: a channelization code component and a scrambling code component. For example, in a 3GPP UTRA TDD CDMA system, the spreading code consists of a scrambling code and a channelization code. In general, the system includes a scrambling code component to distinguish between a channelization code component to separate a plurality of users in a cell's time slot, and signals originating from within the cell and from other cells Can be used.

1 shows a model of an uplink TDD CDMA encoding, transmission and reception system. User payload data 110 is provided to spreader 120 as channel data (Ch ₁ ; 115). The spreader 120 also receives a spreading sequence 121 (channelization code C _cl 122 and scrambling code C _s1 123). The spreader 120 spreads the user payload data 110 to the spreading sequence 121 by encoding the user payload data 110 with a channelization code C _cl 122 and a specific cell scrambling code C _s1 123 ≪ / RTI >

A user belonging to a common cell may share a specific cell scrambling code (C _s1 ) 123. A user belonging to another cell has another specific cell scrambling code (e.g., C _s2 ). The encoded payload data form an encoded sequence 125 that is provided to a transmitter (xmtr) 130 and then transmitted as a sequence 135 via a wireless channel 140. A wireless channel 140 is formed between the user equipment transmitter 130 and the base station receiver 150. The received signal is then processed by the base station to separate the payload data of each user.

FIG. 2 shows a timeslot burst signal 200, e. G., A timeslot burst signal from a TDD CDMA user. The encoded sequence 125 (FIG. 1) is divided into a first payload section 210 and a second payload section 220. The timeslot burst signal 200 is configured such that the first payload section 210 precedes the midamble sequence 230 and the second payload section 220 follows the midamble sequence 230. The receiver uses the known midamble sequence 230 to determine the impulse response of the wireless channel 140 (FIG. 1). The impulse response assists the receiver 150 in the detection and demodulation process.

The characteristics of spreading sequence 121 composed of channelization code 122 and scrambling code 123 play an important role in radio link performance. For a better understanding of this performance, consider two interfering scenarios, inter-cell interference and intra-cell interference.

Cell-to-cell interference is the interference that occurs from one or more neighboring cells. When significant energy from other cells in addition to energy from the home cell is present at the receiver, the cross-correlation properties of the received waveform have a significant impact on link performance. An overlapping set of channelization codes 122 may be used in two neighboring cells, in a home cell, and in a cell adjacent to a home cell. When an overlapping channel code 122 is used in an adjacent cell, the correlation characteristics of the received waveform are: (1) a scrambling sequence provided in the home cell; (2) a scrambling sequence 121 provided in adjacent interfering cells; And (3) the radio propagation channels through which each signal has passed.

If the cross-correlation properties between two or more signal sequences arriving at the receiver during the same timeslot deteriorate, link performance is impaired. Due to the fact that the scrambling performance of the overall spreading sequence 121 is cell dependent and that the set of available channelization codes 122 is limited to relatively small sets of values, the spreading sequence 121 with poor cross- May continuously interfere with each other, thereby deteriorating system performance continuously.

Unlike cell mutual interference, intra-cell interference is an interference that occurs in a cell. The channelization code is designed to be orthogonalized so that the selected code can have ideal cross-correlation properties. Often, orthogonality is destroyed before the signal reaches the receiver. The orthogonality may be destroyed by the time-dispersive nature of the wireless channel. Orthogonality between two or more uplink signals may also be destroyed when the uplink bursts transmitted in the same timeslot arrive at the base station at different times.

The forward error correction (FEC) combined with the interleaving of wireless transmissions helps overcome short term signal power fluctuations (fading) in the wireless channel. In these schemes, data is encoded over a period spanning multiple fading events and the effect of using the interleaver to produce uniform throughput of bit errors is distributed to the received signal. The power of the forward error correcting code can then recover these small gaps or errors in the received data. If the signal does not substantially deteriorate and forward error correction and interleaving work properly, the underlying information content can be delivered without error.

In addition, forward error correction and interleaving can help to mitigate error bursts caused by the two signal sequences having poor cross-correlation properties at the same time. In addition, forward error correction offers the advantage of reducing the overall variability observed in link performance across users and the advantage of reducing the same variability in the time domain. In addition, the forward error correction can improve the stability of the process of controlling the quality of the signal passing through the wireless link.

The form of time diversity in frame units can be used to mitigate some effect of inter-cell interference on cross-correlation properties. For example, the 3GPP system implements cell parameter ID cycling. In such a system, each cell is assigned two scrambling codes. Frames that are odd-numbered are encoded with a first scrambling code and frames that are even-numbered are encoded with a second scrambling code.

If the system uses a single scrambling code and the system operates in an environment where one selected scrambling code produces consistently bad cross-correlation properties, the cross-correlation properties are always degraded. If the system uses two scrambling codes in the same environment, the cross-correlation properties may be poor for only 1/2 period. If the sequence has bad cross-correlation properties with other signals in one frame, then the next sequence may have better cross-correlation properties in the next frame.

Figure 3 shows a form of code diversity using frame-based cell ID cycling. In this example, the sequence in the odd frame in the first cell (cell # 1) uses a first spreading sequence having a unique scrambling code (C _s1 ). A sequence in an odd frame in a second cell (cell # 2) uses a second spreading sequence having a unique scrambling code (C _s2 ). Similarly, the sequence in the even frame in the first cell (cell # 1) uses the third scrambling code C _s3 . The sequence in the even-numbered frame in the second cell (cell # 2) uses the fourth scrambling code (C _s4 ). In this example, the codes used in the odd frame have poor cross-correlation characteristics between the first cell and the second cell. Fortunately, the code used in even frames has good cross-correlation properties. The change in cross-correlation properties is due to a change in the specific cell scrambling code (C _si ).

In this example, additional link performance can be realized if the forward error correction is performed over a transmission time interval (TTI) that is greater than or equal to two radio frames (20 ms). FEC may be implemented on frame pairs in a cell. Interleaving can be used to further improve link performance.

In addition to the scrambling code that varies with the cell parameter (ID), the midamble sequence can also be changed. This may result in the same randomization of the cross-correlations between arriving midamble waveforms, which is used at the receiver to compute better channel estimates.

By moving more error correction and retransmission control functionality down from the base station controller, such as the RNC, to the base station, such as Node-B, the wireless communication system can reduce control, transmission and retransmission latencies. For packet data, minimizing the transmission latency is a goal in providing high end-user perception of throughput. High latency simply appears as a slow data link to the user, while low latency forms the perception that the user is connected through a high throughput data link.

In current 3GPP systems of frame-based cell ID cycling, data must be transmitted over a 20 ms TTI in order to realize the benefits of code diversity. This means that data transmissions above 20 ms TTI immediately introduce latency through the wireless link, but transmission using TTIs less than 20 ms can not realize the benefits of frame based code diversity. In the current 3GPP scheme, frame based code diversity is unsuitable for transmission with low latency (< 20 ms).

In addition, current 3GPP cell parameter ID cycling is intended to improve the situation of the cell mutual interference case. In the case of intra-cell interference, it is not an object of attention.

In some embodiments of the invention, the TTI is considered not to be greater than one radio frame. Each transmission within the TTI consists of one or more time slots. 3.84 Mcps (Megachips per second) In 3GPP UTRA TDD, one radio frame has a length of 10 ms, includes 15 time slots, and up to 14 times slots can be allocated for uplink traffic. Within the system, timeslot and channelization code resources are likely to be allocated relatively quickly (e.g., on a frame-by-frame basis) by network entities such as base stations or base station controllers.

The number of timeslots allocated to the user and the number of allocated channelization codes are likely to change according to the data traffic demand of the user. Generally, a user is allocated more than one time slot per radio frame for the high throughput required by the user. In some embodiments, a single code is allocated for each uplink timeslot. In another embodiment, multiple codes are allocated per uplink timeslot. In some embodiments, a single code is assigned per downlink timeslot. In another embodiment, multiple codes are allocated per downlink timeslot.

In some embodiments, the codes or codes used for transmission are changed for each user within a radio frame. Thus, in transmissions that span multiple code modification cycles within a TTI and forward error correction is performed, the benefits of code diversity can be realized and system capacity and performance can be increased.

In some embodiments, by changing the spreading sequence, the spreading sequence may be changed for each time slot. In some embodiments, the spreading sequence is changed for each time slot by changing the scrambling code from time slot to time slot. In another embodiment, the spreading sequence may be changed from a half (1/2) time slot to a half time slot. That is, the first half of the payload (210 in FIG. 2) is encoded with the first spreading sequence and the second half of the payload (220 in FIG. 2) with the second spreading sequence. If a cell is assigned only two scrambling codes and is encoded on the basis of a half time slot, all timeslots are encoded in the same scramble code pair. If a cell is allocated only four scrambling codes and is encoded on the basis of a half time slot, every other time slot is encoded with the same scrambling code pair. If a cell is assigned two scrambling codes and is encoded on a timeslot basis, every other timeslot is encoded with the same scrambling code.

4 shows a code diversity transmission scheme for low latency transmission. 4 may be applied to either the uplink signal or the downlink signal. At 410, user data is provided to the encoding system. Some embodiments include an FEC unit 420, an interleaving unit 430, and a code mapping / distribution unit 440. Other embodiments do not include an FEC unit 420 and / or an interleaving unit 430. In some embodiments, user data is provided to FEC unit 420. [ The output of the FEC unit 420 is provided to the interleaving unit 430. The input to the code mapping / distribution unit 440 may be user data from 410 or user data provided through either or both of 420 and 430. [

In some embodiments, user data is processed by either or both of the FEC unit 420 and the interleaving unit 430, as described above. User data that has not been pre-processed or pre-processed is provided to the code mapping / distribution unit 440. The code mapping / distribution unit 440 parses the user data into a sequence of symbols, where the symbols represent one or more bits. When cyclic encoding is performed per time slot, the code mapping / distribution unit 440 parses the user data into time slot blocks of data.

4 shows a code mapping / distribution unit 440 for parsing user data into three paths. The first path of user data is encoded into code sequence 1. The second path of the user data is encoded into code sequence 2. The Nth path of the user data is encoded into a code sequence N. [ The code sequence 1 may represent a unique scrambling code. In another approach, code sequence 1 may represent a unique spreading code. In this example, the three codes (code sequences 1, 2, and N) are different. Three timeslots filling the uplink traffic in one frame are encoded into three different codes. In the one frame repeating pattern, the same three codes can be used for the next three uplink timeslots in the next frame. In the two-frame repeat pattern, three other codes may be used for the next three uplink timeslots in the second frame, and thereafter, for the next three uplink timeslots in the third frame again The first three codes can be used again.

In some embodiments, each uplink timeslot in a frame is assigned a spreading sequence. Some but not all of the spreading sequences used in the frame may be the same. In some embodiments, each uplink timeslot in a frame is assigned a different spreading sequence. In these embodiments, none of the spreading sequences used in the frame is the same.

In addition to cycling the scrambling sequence or spreading code, the UE may also cycle or modify the midamble sequence and / or bursts in the uplink as well.

In some embodiments, the code sequence is changed for each section of payload data. In another embodiment, the code sequence is changed for each payload data.

Typically, the 3GPP UTRA TDD receiver is a de-correlating receiver. The de-correlation receiver attempts to release the effects of the radio channel and code sequence being used. A signature sequence is a convolution of a transmission sequence with a radio channel impulse response. This operation is computationally intensive and is typically performed only once per time slot or as needed, such as when the wireless channel or code used is changed. Thus, a very complex portion of the receiver can be executed at least at a changing rate of the code sequence being transmitted.

The change in the code used in each time slot may be the same for each user or may be different among users. That is, the code change can occur in units of cells, users, or both.

In addition, the channelization code component or the scrambling code component of the overall spreading sequence may be changed, or both components may be changed. There is another possibility that additional variation code components may be applied to existing codes. By changing the sequence within a short term TTI (e.g., within 10 ms), code diversity can be realized while maintaining low latency transmissions.

5 shows a form of code diversity using time slot based cell ID cycling. In the first embodiment, a code repetition pattern of all frames is used. The frame is shown to have four uplink time slots (TS ₁ to TS ₄ ). A code sequence (C _s1 ) is used on the user data located in the _first timeslot (TS ₁ ). A code sequence (C _s2 ) is used on the user data located in the _second timeslot (TS ₂ ). A code sequence (C _s3 ) is used on the user data located in the third time slot (TS ₃ ). A code sequence (C _s4 ) is used on the user data located in the fourth time slot (TS ₄ ). Thus, the first frame of uplink timeslots utilizes the code sequence (C _s1 , C _s2 , C _s3 and C _s4 ). Since all the frames are repeating patterns, the next frame also uses the code sequences ( _Cs1 , _Cs2 , _Cs3 and _Cs4 ).

In the second example, a code repetition pattern of every other frame is used. The first frame is shown to have four uplink time slots (TS ₁ to TS ₄ ). A code sequence (C _s1 ) is used on the user data located in the _first timeslot (TS ₁ ). A code sequence (C _s2 ) is used on the user data located in the _second timeslot (TS ₂ ). A code sequence (C _s3 ) is used on the user data located in the third time slot (TS ₃ ). A code sequence (C _s4 ) is used on the user data located in the fourth time slot (TS ₄ ). Thus, the first frame of uplink timeslots utilizes the code sequence (C _s1 , C _s2 , C _s3 and C _s4 ). Since one frame is filtered out a repeated pattern, the second frame is used in a code sequence (C _{s5, s6} C, C and C _{s7 s8).} The code sequences C _s1 , C _s2 , C _s3 and C _s4 are again used as shown in the third frame.

In some embodiments of the invention, the method changes the scrambling code assigned to the cell on a timeslot basis. To enable accurate decoding, the variation pattern may be known to both the user and the base station, and may be synchronized between the transmitter and the receiver. In some embodiments of the invention, the code variation pattern is predetermined and known a priori by the transmitter and the receiver. In some embodiments of the invention, the code variation pattern is signaled to the user terminal by the network at the beginning of the connection or during the connection. In some embodiments of the invention, the code variation pattern is derived by an algorithm known to both the transmitter and the receiver, and the seed-value or other parameter is signaled at the beginning or during the connection. In some embodiments of the invention, the code variation pattern is a function of system parameters known to both the transmitter and the receiver. For example, the system parameter may be a system frame number. Further, in some embodiments of the present invention, the code variation pattern itself may be changed at a predetermined time when it is determined or signaled by the network or a priori known to both the receiver and the transmitter.

In some embodiments of the invention, the spreading codes used may be generated from a conventional set of predetermined scrambling and channelization sequences, or may be generated from entirely new sequences. In another approach, a new set of sequences may be derived using computing means or algorithm means that utilize an existing sequence as function inputs.

In some embodiments of the present invention, the midamble sequence used for transmission may also be changed in the same manner as for the code applied to the payload section of the burst (s).

Some embodiments of the present invention provide a TDD CDMA system comprising a transmitter capable of altering a code sequence used for transmission more than once during transmission of one or more interleaved forward error correction data units, wherein the code diversity advantage And a transmission method in a TDD CDMA system. The code sequence may be changed multiple times within the radio frame. Some embodiments of the present invention provide a receiver that is synchronized with a variation code pattern provided in a transmitter to perform deinterleaving and error correction decoding of the received data unit (s).

An embodiment of the present invention provides a method for changing transmission code at least once upon transmission of a forward error correction data unit by means of modifying a scrambling code, wherein the scrambling code used is (1) for 3GPP TDD CDMA Originating from an existing set of scrambling codes; (2) derived by computing means or algorithm means from an existing set of scrambling codes determined for 3GPP TDD CDMA; And / or (3) any new set of scrambling codes. Some embodiments of the present invention provide a method for changing a transmission code more than once during transmission of a forward error correction data unit by means of modifying the channelization code, wherein the channelization code comprises: (1) Are members of a set of channelization codes determined for the channelization code; And / or (2) any new set of channelization codes. Some embodiments of the present invention provide a method for changing a transmission code more than once during transmission of a forward error correction data unit by means of modifying both the scrambling code and the channelization code. Some embodiments of the present invention provide a method for altering a transmission code upon transmission of a forward error correction data unit by means of applying an additional code to an existing channelization code and a scrambling code.

Some embodiments of the present invention provide a method in which the code variation pattern is known a priori and implicitly to both the transmitter and the receiver. Some embodiments of the present invention provide a way in which a code variation pattern is explicitly signaled to a transmitter by a network or a base station. Some embodiments of the present invention provide that code variation patterns are derived through algorithm means or computation means based on parameters; Signaled to the transmitter by the network or base station; And / or other system parameters known to both the transmitter and the receiver, or signaled to the transmitter by the network. Some embodiments of the invention provide a way in which the transmitted code is changed in time slot units. Some embodiments of the invention provide a way in which the transmitted code is changed on a sub-timeslot basis (e.g., per data payload, per payload, or per symbol). Some embodiments of the present invention provide a method by which the transmitted code is changed per time slot or sub time slot by means of changing scrambling code and / or channelization code and / or additional provided code.

Some embodiments of the present invention provide a method as described for any of the above-described features provided in 3GPP TDD CDMA uplink systems, including legacy uplink channels and / or enhanced uplink channels. Some embodiments of the present invention provide a method as described for any of the above-described features provided in a 3GPP TDD CDMA downlink system, including legacy downlink channels, HSDPA and future downlink channels. Some embodiments of the present invention provide any of the methods described above in which the midamble sequence used for burst transmission is also changed as a variation function applied to the scrambling / channelization / additional code.

While the present invention has been described by way of specific embodiments and illustrative figures, it is to be understood that the invention is not limited to those embodiments and drawings. The drawings provided are for illustration only and are not drawn to scale. Rather, it can be exaggerated at a certain rate and others can be reduced. These drawings are intended to illustrate embodiments of the present invention in which the present invention can be suitably performed and understood by those skilled in the art. It is, therefore, to be understood that the invention can be practiced with numerous modifications and variations that fall within the scope of the appended claims. The detailed description is not intended to limit or omit the invention to the particular forms disclosed.

Also, while listed separately, a plurality of means, elements, or method steps may be implemented by, for example, a single unit or processor. In addition, although individual features may be included in separate claims, these features may advantageously be combined, and the inclusion in separate claims means that a combination of features is not feasible and / or advantageous It does not. Also, the inclusion of features in the category of claims does not mean only a limitation to such a category, but means that the feature is equally applicable to other claim categories depending on the degree of fitness. Also, the order of the features in the claims does not imply any particular order in which the features should be operated, and more specifically, the order of the individual steps in the method claim must necessarily be performed in that order It does not. Rather, these sequences may be performed in any suitable order.

110: User payload data
120: diffuser
121: spreading sequence
122: Channelization code
123: scrambling code

Claims (19)

Associating a first portion of the user data with a first portion of a frame and associating a second portion of the user data with a second portion of the frame, A method for transmitting data over a link from a first radio to a second radio,
Encoding a first portion of the user data into a first spreading sequence comprising a first channelization code component and a first scrambling code component;
Encoding a second portion of the user data into a second spreading sequence comprising a second channelization code component and a second scrambling code component, the first channelization code component being different from the second channelization code component - Wow;
Transmitting a first portion of the encoded user data in a first portion of the frame from the first wireless to the second wireless;
Transmitting a second portion of the encoded user data in a second portion of the frame from the first wireless to the second wireless;
Wherein forward error correction is performed on the user data over a transmission time interval,
Wherein a first portion of the frame comprises a first timeslot of the frame and a second portion of the frame comprises a second timeslot of the frame and the second timeslot is different from the first timeslot,
Wherein the first scrambling code and the second scrambling code are generated by the first radio and the second radio Cell, changes in units of time slots according to the variation pattern,
Wherein the scrambling code changes at least once during transmission of the forward error correction data unit. 2. The method of claim 1, wherein a timeslot comprises a first portion of the frame and a second portion of the frame. 2. The method of claim 1, wherein the first timeslot and the second timeslot are adjacent time slots. 2. The method of claim 1, wherein the first timeslot and the second timeslot are time slots separated by one or more timeslot periods. The method according to claim 1,
Encoding a third portion of the user data into a third channelization code component and a third scrambling code component;
Encoding a fourth portion of user data with a fourth channelization code component and a fourth scrambling code component, wherein the fourth channelization code component is different from the third channelization code component;
Transmitting a third portion of the encoded user data in a first portion of a second frame from the first radio to the second radio, the first portion of the second frame corresponding to a first portion of the first frame - Wow;
Transmitting a fourth portion of encoded user data in a second portion of the second frame from the first radio to the second radio, wherein a second portion of the second frame includes a second portion of the first frame Corresponding to -
Further comprising the steps of: 2. The method of claim 1, further comprising performing forward error correction over a transmission time interval of a single frame. 2. The method of claim 1, further comprising: performing forward error correction across a plurality of time slots in a frame. 8. The method of claim 6 or 7, further comprising: performing interleaving over a plurality of time slots. 2. The method of claim 1, wherein the first scrambling code component is different from the second scrambling code component. The method according to claim 1,
Wherein transmitting the first portion of the encoded user data in the first portion of the frame from the first wireless to the second wireless includes transmitting a first midamble sequence,
Wherein transmitting the second portion of the encoded user data in the second portion of the frame from the first radio to the second radio comprises transmitting a second midamble sequence different from the first midamble sequence / RTI &gt; The method according to claim 1,
Determining the first spreading sequence for a first portion of the user data;
Determining the second spreading sequence for a second portion of the user data
Further comprising the steps of: 2. The method of claim 1, wherein the link comprises an uplink, the first radio comprises a mobile radio, and the second radio comprises a base station. 2. The method of claim 1, wherein the link comprises a downlink, the first radio comprises a base station, and the second radio comprises mobile radio. Logic for accepting user data; A code diversity transmitter comprising code mapping and distribution logic operative to parse the user data into a first portion of user data and a second portion of user data,
And to encode a first portion of the user data into a first spreading sequence comprising a first channelization code component and a first scrambling code component and to generate a second portion of the user data with a second channelization code component Encoding logic operable to encode the first channelization code component into a second spreading sequence comprising two scrambling code components, the second channelization code component being different from the first channelization code component;
A transmitter coupled to the encoding logic and operative to transmit encoded user data; And
FEC logic that operates to perform forward error correction (FEC) on user data over a transmission time interval
/ RTI &gt;
Wherein a first portion of a frame comprises a first timeslot of the frame and a second portion of the frame comprises a second timeslot of the frame and the second timeslot is different from the first timeslot,
Wherein the first scrambling code and the second scrambling code are generated by the first radio and the second radio Cell, changes in units of time slots according to the variation pattern,
Wherein the encoding logic is configured to change the scrambling code one or more times during transmission of the forward error correction data unit.
Code diversity transmitter. 15. The code diversity transmitter of claim 14, wherein the FEC logic is coupled between logic accepting the user data and the code mapping and distribution logic. 15. The code diversity transmitter of claim 14, further comprising interleaving logic for performing interleaving, the interleaving logic being coupled between the code accepting user data and the code mapping and distribution logic. 15. The code diversity transmitter of claim 14, wherein the first portion of the user data comprises a timeslot block of data. 15. The code diversity transmitter of claim 14, wherein the first scrambling code component is different from the second scrambling code component. Means for associating a first portion of a user data with a first portion of a frame and means for relating a second portion of the user data to a second portion of the frame, An apparatus for transmitting data via a link from radio to a second radio,
Means for encoding a first portion of the user data into a first spreading sequence comprising a first channelization code component and a first scrambling code component;
Means for encoding a second portion of the user data into a second spreading sequence comprising a second channelization code component and a second scrambling code component, the first channelization code component being different from the second channelization code component; - and;
Means for transmitting a first portion of the encoded user data in a first portion of the frame from a first wireless to a second wireless;
Means for transmitting a second portion of the encoded user data in a second portion of the frame from a first wireless to a second wireless,
Forward error correction is performed on the user data over the transmission time interval,
Wherein a first portion of the frame comprises a first timeslot of the frame and a second portion of the frame comprises a second timeslot of the frame and the second timeslot is different from the first timeslot,
Wherein the first scrambling code and the second scrambling code are generated by the first radio and the second radio Cell, changes in units of time slots according to the variation pattern,
Wherein the means for encoding is configured to change the scrambling code one or more times during transmission of the forward error correction data unit.
Data transmission device.

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